First, we lock a distinct SYSDBA."pseudo table" for read on a RowHash to prevent global deadlock for SYSDBA.T6.

2)

Next, we lock a distinct SYSDBA."pseudo table" for read on a RowHash to prevent global deadlock for SYSDBA.T5.

3)

We lock a distinct SYSDBA."pseudo table" for read on a RowHash to prevent global deadlock for SYSDBA.T4.

4)

We lock a distinct SYSDBA."pseudo table" for read on a RowHash to prevent global deadlock for SYSDBA.T3.

5)

We lock a distinct SYSDBA."pseudo table" for read on a RowHash to prevent global deadlock for SYSDBA.T2.

6)

We lock a distinct SYSDBA."pseudo table" for read on a RowHash to prevent global deadlock for SYSDBA.T1.

7)

We lock SYSDBA.T6 for read, we lock SYSDBA.T5 for read, we lock SYSDBA.T4 for read, we lock SYSDBA.T3 for read, we lock SYSDBA.T2 for
read, and we lock SYSDBA.T1 for read.

8)

We execute the following steps in parallel.

1)

We do an all-AMPs JOIN step from SYSDBA.T3 by way of a RowHash match scan with no residual conditions, which is joined to
SYSDBA.T4. SYSDBA.T3 and SYSDBA.T4 are left outer joined using a merge join, with a join condition of ("SYSDBA.T3.E = SYSDBA.T4.G"). The
result goes into Spool 2, which is built locally on the AMPs. Then we do a SORT to order Spool 2 by row hash. The size of Spool 2 is
estimated with low confidence to be 22 rows. The estimated time for this step is 0.06 seconds.

2)

We do an all-AMPs JOIN step from SYSDBA.T5 by way of a RowHash match scan with no residual conditions, which is joined to
SYSDBA.T6. SYSDBA.T5 and SYSDBA.T6 are left outer joined using a merge join, with a join condition of ("SYSDBA.T5.I = SYSDBA.T6.K"). The
result goes into Spool 3, which is duplicated on all AMPs. Then we do a SORT to order Spool 3 by row hash. The size of Spool 3 is
estimated with low confidence to be 264 rows. The estimated time for this step is 0.06 seconds.

3)

We do an all-AMPs JOIN step from SYSDBA.T1 by way of a RowHash match scan with no residual conditions, which is joined to
SYSDBA.T2. SYSDBA.T1 and SYSDBA.T2 are left outer joined using a merge join, with a join condition of ("SYSDBA.T1.A = SYSDBA.T2.C"). The
result goes into Spool 4, which is built locally on the AMPs. Then we do a SORT to order Spool 4 by row hash. The size of Spool 4 is
estimated with low confidence to be 22 rows. The estimated time for this step is 0.06 seconds.

9)

We do an all-AMPs JOIN step from Spool 2 (Last Use) by way of a RowHash match scan, which is joined to Spool 3 (Last Use). Spool 2
and Spool 3 are left outer joined using a merge join, with a join condition of ("G = I"). The result goes into Spool 5, which is duplicated
on all AMPs. Then we do a SORT to order Spool 5 by row hash. The size of Spool 5 is estimated with low confidence to be 1,944 rows. The
estimated time for this step is 0.08 seconds.

10)

We do an all-AMPs JOIN step from Spool 4 (Last Use) by way of a RowHash match scan, which is joined to Spool 5 (Last Use). Spool 4
and Spool 5 are left outer joined using a merge join, with a join condition of ("C = E"). The result goes into Spool 1, which is built
locally on the AMPs. The size of Spool 1 is estimated with low confidence to be 1,188 rows. The estimated time for this step is 0.20
seconds.

11)

Finally, we send out an END TRANSACTION step to all AMPs involved in processing the request.

->

The contents of Spool 1 are sent back to the user as the result of statement 1. The total estimated time is 0.34 seconds.